Abstract
Treatment of congenital diaphragmatic hernia (CDH) challenges obstetricians, pediatric surgeons, and neonatologists. Persistent pulmonary hypertension (PPHT) associated with lung hypoplasia in CDH leads to a high mortality rate at birth. PPHT is principally due to an increased muscularization of the arterioles. Management of CDH has been greatly improved by the introduction of prenatal surgical intervention with tracheal obstruction (TO) and by more appropriate postnatal care. TO appears to accelerate fetal lung growth and to increase the number of capillary vessels and alveoli. Improvement of postnatal care over the last years is mainly due to the avoidance of lung injury by applying low peak inflation pressure during ventilation. The benefits of other drugs or technical improvements such as the use of inhaled nitric oxide or extracorporeal membrane oxygenation (ECMO) are still being debated and no single strategy is accepted worldwide. Despite intensive clinical and experimental research, the treatment of newborn with CDH remains difficult.
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Introduction
Congenital diaphragmatic hernia (CDH) combines a muscle defect between the abdomen and the thoracic cavity with pulmonary hypoplasia. The muscle defect leads to a herniation of the abdominal viscera into the thoracic cavity [12, 44]. It usually stems from the left posterolateral part of the muscle and is called Bochdalek hernia [55]. The Morgagni hernia concerns the antero-medial retrosternal portion of the diaphragm and the esophageal hiatal hernia arises from a physiological orifice. Riverius was the first to describe a CDH in 1679, Morgagni described different types of diaphragmatic hernia in 1761, and in the nineteenth century Victor Bochdalek described his autopsies of children with CDH.
CDH occurs in 1/2,500 to 1/5,000 live births. No specific causal gene defects have been identified in humans and most cases are sporadic. A few drugs such as pyridoxine, thalidomide, quinine, and antiepileptic drugs have been implicated in the occurrence of CDH. However, its true incidence is probably higher because some fetuses with severe CDH die in utero and are spontaneously aborted. Eighty-four percent of CDH are left-sided, 14% right-sided, and 2% bilateral [58, 104]. CDH is often associated with cardiac, gastrointestinal, genitourinary, skeletal or neural anomalies and with trisomies [48, 58]. The incidence of associated anomalies in infants born with a CDH ranges from 10% to 40% [27]. In about 30% of cases, these malformations appear as skeletal defects such as limb reduction or costovertebral defects [97]. Cardiac malformations such as hypoplasia of the aortic arch, tetralogy of Fallot, transposition of the great vessels or aortic coarctation occur in about 25% of cases [96]. Congenital tracheal stenosis, tracheal bronchus or other tracheal malformations can also be found in association with CDH [74]. Neural tube defects seem to be the most common findings in infants with CDH who died in utero [96].
CDH alone has a mortality rate of 20% and the degree of associated pulmonary hypoplasia and the severity of pulmonary hypertension remain the major determinant of survival [89]. When the associated anomalies are severe, the mortality rate can be as high as 90% [58]. Stege et al. [90] showed that the two factors which clearly influence postnatal mortality are the timing of the termination of gestation and the presence of additional anomalies. They showed that the survival rate of infants diagnosed with CDH has not improved in the past 10 years despite new therapies, and that half of the cases had not been detected by antenatal scanning, leading to the birth of infants with a life-threatening condition in an unprepared obstetric unit. They also noted that CDH had remained undiagnosed in some infants who had died immediately after birth [90]. Therefore, the overall mortality of children with a CDH is difficult to determine.
Long-term compression of fetal lungs by the herniation of the viscera into the thoracic cavity results in pulmonary underdevelopment and lung hypoplasia [3, 36, 55]. This was confirmed in both ipsilateral and contralateral pulmonary specimens by an analysis of lung volumes and weights during autopsies of humans and of animal models [76]. Structural alterations in CDH lungs are a decrease of the total arteriolar cross-sectional area and a significant adventitial and medial wall thickening in pulmonary arteries of all sizes, with abnormal muscularization of the small pre-acinar and intra-acinar arterioles, leading to a persistent pulmonary hypertension (PPHT) which causes the death of babies before or after birth [18, 67]. The probability of survival in children born with CDH is therefore determined mainly by the severity of lung hypoplasia and the presence of PPHT causing abnormal pulmonary compliance, refractory respiratory failure at birth, hypoxemia, right to left extrapulmonary shunting of blood, progressive acidosis (Fig. 1) and heart failure [51, 68].
Even fetuses which survive up to delivery have significant lung hypoplasia and impaired lung function which lead to long-term morbidity. Since the 1980s, there have been many advances in the care of neonates, in particular the introduction of drugs such as the surfactant, and later the discovery by Furchgott and Zawadzki [32] of nitric oxide (NO), which can reduce PPHT in most pathologies. Other advances were the use of high-frequency oscillation (HFO) and extracorporeal membrane oxygenation (ECMO). Although all these advances have proved efficient in most diseases related to PPHT, treatment of CDH remains difficult and challenging as no single treatment has yet proved to be very efficient [100]. Surgery “in utero”, with the insertion of a temporary tracheal occlusion (TO) to improve lung growth and lung capacity, is a new approach in the treatment of children with CDH but its indication in cases of fetuses with severe lung hypoplasia is still debated.
Anomalies of pulmonary vascularity [117], such as hyperplasia of the smooth muscle cells play a decisive role in maintaining a high pulmonary vascular resistance (PVR), pulmonary vascular compliance and therefore blood flow [34]. The smaller arteries, those with an external diameter of less than 200 µm, are predominantly responsible for PVR [99]. To be more precise, pulmonary vascular abnormalities in CDH consist in a decreased number of pulmonary arteries per unit of lung volume and in the peripheral muscularization of small arteries, with medial and adventitial thickening [85, 117]. Increased adventitial and medial thickness of the pulmonary arterial wall is the most striking structural changes which have been reported in patients with CDH complicated by PPHT [34]. The presence of abnormally thick-walled pulmonary arteries in newborn with CDH suggests that their intrapulmonary arteries may become excessively muscularized during fetal life and unable to adapt normally at birth. In fetuses, studies of blood flow with a 3-D Doppler showed decreased vascularity, decreased pulmonary blood flow, and decreased pulmonary blood flow per volume of blood vessels [80].
Management
There is to this day no consensus on the treatment of babies with PPHT. Studies on the treatment of these children have to be interpreted carefully for different reasons: firstly, comparisons of the degree of herniation are difficult, and the criteria applied to determine whether a CDH is moderate or severe are not always the same and may bias the appraisal of patients and affect the decision on the mode and timing of the treatment; secondly, no criteria for the selection of a particular treatment have been validated in large series, and the choice of treatment depends largely on the strong belief of the team-leader; and thirdly, the survival rate is higher in large centers, where a great number of children are born or transferred every year, than in smaller centers where these cases are few and far between [47].
The evaluation of a fetus suspected of presenting CDH includes a prenatal high-resolution ultrasound (US) examination to confirm the diagnosis. Between 40% and 60% of infants with CDH are diagnosed prenatally [33]. Normally, the first sign evidenced by US is the presence of fluid-filled loops of bowel in the thorax. The small bowel and the stomach are both involved in 90% of cases. A bad prognosis can be presaged before birth on the basis of different signs and measurements provided by US: an early diagnosis at 24 weeks of gestation with a large muscular defect, a dilated intrathoracic stomach, a herniated left lobe of the liver and the presence of a polyhydramnios are predictive of severe pulmonary hypertension at birth and of a poor outcome [94]. Subsequent US examinations are performed to assess the contents of the hernia, evaluate any associated malformations and measure the lung–heart ratio (LHR). It is important to know the position of the liver because the prognosis for a baby with a herniated liver is not good. A US–Doppler examination can be done to check the position of the umbilical vein and of the hepatic vessels. Various indexes have been proposed to evaluate the prognosis after a US examination. In 2000, Suda [94] showed that the most significant prognostic factor was the modified McGoon index, which is the diameter of the proximal pulmonary artery indexed to the descending aorta. An index of 1.3 or less predicts mortality with a sensitivity of 85% and a specificity of 100%.
Magnetic resonance imaging (MRI) realized prenatally can be of importance to resolve a doubt about the position of the liver, to evaluate the volume of the lungs or to distinguish a CDH from other malformations such as a cystic adenomatoid malformation, pulmonary sequestration, bronchogenic cyst, enteric cysts or mediastinal teratoma. This technique is an excellent mode of imaging when an exquisite anatomical detail has to be discussed precisely. Karyotyping is also mandatory as CDH is frequently associated with chromosomal anomalies.
Several choices can be envisioned and proposed to the parents of a child with a CDH diagnosed prenatally and a bad prognosis: interrupt the pregnancy (before 24 weeks), let the pregnancy follow its course up to delivery, or consider prenatal surgery and TO. As CDH has a significant mortality rate, there is a hope that an intervention in utero may improve the outcome for the child.
Prenatal management
A multidisciplinary team includes at least neonatalogists, obstetricians, pediatric surgeons, geneticists, and cardiologists. Fetal surgery is normally shared by pediatric surgeons and obstetricians but the management of each case and the decision to perform surgery must be the result of a multidisciplinary discussion which takes into account the context of the malformation, the various signs indicative of its gravity, the gestational age at diagnosis, and the family’s history and likelihood to consent to the procedure [14].
In 1990, Harrison et al. in San Francisco were the first to operate in utero on children with CDH [38]. This new surgical approach encountered difficulties, and its results were not always completely successful. There was a high rate of preterm deliveries due to infection and difficulties in maintaining tocolysis. The reduction of a liver herniated into the thorax proved difficult and provoked an obstruction of the umbilical blood flow and the death of the fetus [39].
Tremendous advances were made following the observation that the prevention of a normal efflux of intraluminal lung liquid has a positive influence on lung growth by stimulating the development of pulmonary parenchyma [114]. This finding led to the concept that occluding the trachea before birth (Fetal Tracheal Occlusion or FETO) could enhance lung growth and improve the outcome after birth [21, 30, 40, 41].
Animals with CDH treated by tracheal occlusion developed lungs whose appearance and function were normal, and their rate of survival was significantly improved in comparison to control animals [23]. In sheep and rats with a nitrofen-induced CDH [54, 63], tracheal occlusion results in lung growth, and morphometric studies show a decrease in the thickening of the small pulmonary arteries [50, 54].
Attempts were made to explain the mechanism of lung adaptation after FETO by searching for the presence of such molecules as vascular endothelial growth factor-A (VEGF-A), platelet-derived growth factor-B (PDGF-B), insulin-like growth factor-II (IGF-II), mitogen-activated protein kinase (MAPK) or endothelin-1 (ET-1) [11, 37, 111].
Indication and measurements
Fetal surgery is a treatment which is available only in the few centers which receive a sufficient number of cases [47]. While counseling on the possibility of fetal surgery and the organization of the delivery is normally provided by a team of neonatologists, gynecologists, geneticians, and pediatric surgeons, fetal surgery itself relies also on the expertise of other teams such as radiologists and on the availability of special instrumentation, and its complexity precludes its widespread application and limits its execution to a few highly specialized fetal treatment centers.
Although a variety of indexes have been suggested, there are as yet no real markers to determine the gravity of the pulmonary hypertension which will be found at birth. The capability of identifying high-risk fetuses in the prenatal period is crucial in order to select those fetuses which will benefit from prenatal high-risk interventions. Actually, two criteria are taken into consideration in the selection of high-risk fetuses:
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The position of the liver. Fetuses whose liver is partially herniated into the thoracic cavity have a 50% chance of survival [19, 80].
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The ratio between lung and head (Fig. 2), called LHR [59, 60, 84]. Group A: A LHR lower than 0.6 points to a very poor outcome for the fetus, with extreme lung hypoplasia and a mortality rate of almost 100%. Group B: a ratio between 0.6 and 1 gives the fetus which has a severe lung hypoplasia a predictive survival rate of 15 to 60%. FETO is normally proposed for these babies. Group C: a ratio in the range of 1.0 to 1.6 gives the child a 66% chance of survival and a predictive survival rate of more than 83% [60, 84]. However, even for these babies, the indication of FETO is under discussion as the beneficial effect of FETO has not yet been proved. In a prospective series in 1997, Lipshutz [60] showed that no fetus having a LHR of less than 1 survived to a postnatal age of 60 days, and that only children with a LHR greater than 1.4 could survive. But it has also been demonstrated that LHR is not a predictive factor in fetuses with a left CDH and a normal position of the liver [84].
On the basis of these two criteria, the FETO procedure, with the PLUG being inserted between 26 and 28 weeks of gestation, and the UNPLUG performed at 34 weeks of gestation, is proposed for fetuses showing (1) a LHR of less than 1, (2) a herniation of a large portion of the liver including part of the left lobe, (3) a normal genetic karyotype, (4) no associated abnormalities and (5) a singleton pregnancy at 25 weeks of gestation. One must also make sure that the anesthesia and surgery will not put the mother at risk. The timing and duration of the occlusion are the subjects of discussion and research as they are crucial to the beneficial effect of the procedure, i.e., increased pulmonary stretch and accelerated growth of airways and pulmonary vessels.
Surgery
After routine preoperative laboratory studies and a physical examination, an ultrasound examination is carried out to check the viability of the fetus. Indomethacin is given in the morning to provide uterine relaxation. An epidural block is placed to allay the pain of the mother and the fetus. Compression stockings are used as a precaution against thromboembolic risks. Anesthesia is realized with isoflurane inhalation to ensure uterine relaxation. The patient is draped for surgery.
Two important advances in this prenatal surgery have been developed: the first advance is the development of the technique which allows the procedure to be performed fetoscopically, whereby a balloon is inserted percutaneously through a 3.3 mm incision to create the endoluminal tracheal occlusion at 26–28 weeks of gestation. Previously, surgery in utero entailed a hysterotomy: the maternal abdomen was opened by a low transverse laparotomy, a hysterotomy was performed under ultrasound control. A pulse oximetry device was applied to the hand and the throat was exposed for a midline neck dissection in order to isolate the trachea. The trachea was occluded by two hemoclips facing each other. Closure was then executed layer by layer. Continuous patient-controlled epidural analgesia was provided for the relief of maternal postoperative pain. Tocolysis was ensured by intravenous doses of magnesium sulfate and indomethacin and continued to the end of the pregnancy. Bed rest was normally prescribed for the mother, who was monitored for signs and symptoms of preterm labor. Follow-up ultrasound examinations were performed to measure lung parenchyma and check on the expected gradual increase in lung volume. But the rate of survival of the fetuses was low and the morbidity of survivors not acceptable [39]. Then, in 2000, it was reported that fetoscopic endoluminal tracheal occlusions had been performed on lamb fetuses [77] with endoscopic instruments. This type of surgery, called FETENDO for “fetal endoscopic surgery”, was later also performed on human fetuses [21, 40, 41].
The second advance was the improvement in the material used for tracheal occlusions. The placement below the vocal cords of a water impermeable and expandable polymeric foam in a gelatin capsule, introduced into the trachea by means of a fetoscope with a detachable balloon occlusion system, appears to be well tolerated by the fetus and to stimulate excellent lung growth without causing tracheal damage [20]. The fetoscope has a diameter of 1.2 mm, in a sheath whose diameter measures 3 mm. This method represents a marked advance on the fetoscopic fetal occlusion with clips, which can give rise to numerous surgical complications [41].
The restoration of airway potency by removal of the balloon can be realized prior to birth at 34 weeks of gestation, or by “Ex utero Intrapartum Treatment (EXIT)” during delivery. The first method avoids the drawback of a long-term tracheal occlusion which provokes the differentiation of type II pneumocytes into type I pneumocytes with surfactant deficiency. The procedure is performed prior to birth, at 34 weeks of gestation, either by fetal tracheoscopy, by ultrasound-guided puncture of the balloon using a fetoscope, or by deflation of an expandable balloon [20]. It is carried out under locoregional anesthesia or epidural anesthesia, with prophylactic tocolysis for the mother and fentanyl and pancuronium for the fetus [8]. The risk entailed by this procedure is the “iatrogenic preterm rupture of the fetal membrane” or iPPROM [8, 20].
The second method, EXIT, is a procedure which allows the retrieval of the balloon by tracheoscopy during birth. It can only be performed in institutions which have the appropriate equipment [8]. Labor is induced shortly before term and a laparotomy and a hysterotomy are performed under deep anesthesia to effect uterine relaxation and a good uterine perfusion. The neck of the baby is quickly exposed to allow the removal of the balloon or of the tracheal clips and to do a bronchoscopy. The baby is then intubated and given surfactant. Once it is stabilized in the neonatal intensive care unit, CDH repair is performed.
There is no proof that the outcome is more favorable for children who had a PLUG installed in utero, and a randomized trial was terminated early after showing that they fared no better than children who had not had a PLUG but had been delivered in specialized centers [19, 20]. Nevertheless, further attempts were made on fetuses with a very low prognosis following precise measurements in utero [41]. In 2006, Deprest [19] reported a 75% neonatal survival rate, with 90% patch repair in 66% of operated children, and a 58% neonatal survival rate in 24 consecutive cases of CDH where the mean duration of tracheal occlusion had been 42 days. Although preliminary results of FETO surgery are encouraging, there is as yet no statistical proof that fetal surgery offers better results than postnatal management in terms of survival and long-term morbidity. A randomized study in at least one center should therefore be carried out before FETO surgery becomes widespread.
Postnatal treatment
At birth, babies with CDH will have a flat abdomen, bowel sounds in the chest, cardiac sounds shifted laterally, and breathing difficulties. All efforts should be made to stabilize the cardiopulmonary system during resuscitation with a minimum of iatrogenic injuries. When the CDH is severe, the babies are normally intubated to relieve respiratory distress, and a gastric tube is inserted to decompress the stomach. Ventilation by mask is contraindicated as it may cause a distention of the stomach situated in the thoracic cavity. Arterial and venous access should be acquired through the umbilical vessels in order to obtain blood gas samples and to monitor central venous pressure. Adequate oxygen delivery must be given, with proper temperature regulation and glucose homeostasis. The children must be sedated but muscle paralysis is not encouraged because of its untoward consequences on ventilatory mechanics. Systemic hypotension must be reversed with fluid administration. A chest radiography will usually show gas-filled loops of bowel in the chest along with a shift of the heart to the other side of the defect (Fig. 3). When the CDH is mild, symptoms may not be immediately manifest and can appear only after several months [25].
Advances in neonatal reanimation have greatly improved the outcome of babies born with CDH. The introduction of different types of ventilation, the use of NO and the use of extracorporeal membrane oxygenation (ECMO) are responsible for this improvement. Nevertheless, the benefits of these various techniques and drugs are still being debated and there is as yet no general agreement on the application of one or the other. Even if these techniques taken individually have not proved truly beneficial to babies born with a CDH, their conjunction, or at times their alternance, is beneficial. But more long-term follow-up data on the results of these treatments is needed to assess the mortality and morbidity of children born with a severe CDH. An additional problem is the fact that a truly valid comparison of treatment results can only be made if the children treated present an equal degree of gravity of their CDH.
Conventional ventilation
The optimal mode of ventilation for children with CDH at birth is not defined. Conventional ventilation is based on “gentle” ventilation to avoid any barotrauma which could add another pulmonary problem to the existing pulmonary hypertension. The principle of “gentle” ventilation is based on controlling the peak inflation pressure (18 to 22 cmH2O) by limiting the pressure of ventilation while tolerating an oxygen saturation of 85% and a rise of the arterial pressure of CO2 (PaCO2; permissive hypercapnia), and stimulating spontaneous ventilation [1, 61, 83, 116]. Boix-Ochoa was the first to report that differences in pre- and postductal pH and PaCO2 could be used to differentiate survivors and non survivors, thereby demonstrating the influence of the pH and the PaCO2 on pulmonary vascular tone and ductal shunting [7]. Transporters of gas such as perfluorocarbons can be used as a medium for liquid ventilation. Due to their weak solubility in lipids, they reduce the surface tension of the alveoli and allow a lower pressure of ventilation. Perfluorocarbons can also be used for the local administration of anesthetics and vasodilators [115].
Barotrauma is an additional and leading cause of morbidity and mortality in children with CDH [110]. Studies have demonstrated that increased mortality in children with CDH was due to a high ventilatory rate and a high inspiratory pressure [87]. The mechanisms of ventilator-induced pulmonary damage involve a structural disruption due to lung overdistension and shear–stress forces generated by the repetitive opening and collapse of the atelectatic regions of the lung. These mechanisms induce a capillary leak in the endothelium and epithelium, a rupture of the basement membrane, a leakage of fluid in the alvealor spaces, a general inflammatory response and an impairment of the secretion of surfactant [110].
High-frequency oscillation (HFO)
HFO was introduced in the 1980s in an attempt to ameliorate gas exchange in the lung by avoiding the high inspiratory pressure produced by conventional ventilation and keeping a mean airway pressure of about 15 cmH2O and an amplitude of less than 45 mmHg [6, 57]. HFO can used as the first choice of ventilation for babies born with CDH or when conventional ventilatory strategies fail. There is actually no proof that HFO is better than conventional ventilation [5] but the low-tidal-volume regimen induced by HFO may be less deleterious to the lungs than a high-tidal-volume ventilation [9]. The choice of different modes of ventilation depends largely on the convictions of different teams, who quite try alternate strategies of ventilation when pulmonary hypertension due to CDH does not respond to a first treatment. The teams who chose HFO as a ventilatory strategy reported good results even in children with a bad prognosis [22].
Surfactant
Suen et al. [95] have shown that lung immaturity in babies with CDH can lead to a deficiency of disaturated phosphatidylcholine and a deficiency of surfactant [113]. These findings have not been confirmed by other groups [119]. Most studies on the lack of surfactant were carried out mainly on animal models such as rats, where the production of surfactant seems to be ameliorated by the administration of vitamin A [101, 103].
Even though the use of exogenous surfactant in children with CDH has not been studied in a controlled clinical trial, it constitutes a standard treatment in the fight against PPHT in children with CDH, especially in conjunction with other treatments. It has been proved in animal models (rats and lambs) that lungs with CDH are deficient in surfactant [35]. There is little data on the deficiency of surfactant in human lungs at birth [62, 66, 70]. Recent research has shown that there was no difference in the amount of surfactant in infants with or without CDH [28] and that surfactant treatment during ECMO brought no improvement [13]. But despite the absence of supportive data and of controlled clinical trials to test the effect of exogenous surfactant, it is commonly used in most centers for babies born with CDH [70, 109]. In summary, not only is there no proof that the administration of exogenous surfactant is beneficial, but it may even not be without risk. Complications of the administration of surfactant, such as a drop in arterial pressure, increased cerebral blood flow velocity or non responders, are infrequent [43].
Calcium channel blockers
Although calcium channel blockers are the first treatment for pulmonary hypertension, there are no reports of the use of these drugs in children with PPHT associated with CDH. Nevertheless, these drugs are often used in combination with others, as drug combinations have proved more effective than a single drug alone, especially when a disease is resistant to treatment.
NO
The discovery and the use of NO in recent years is one of the major advances in the understanding of vascular regulation [32]. NO is a potent vasodilator produced by the endothelial cells of vessels, including pulmonary vessels. It improves oxygenation by decreasing PVR reducing pulmonary shunts. In human fetal lungs, the NO pathway is involved in angiogenesis, lung development, and vasorelaxation [53]. NO is known to modulate neutrophils and platelet adhesion, vascular smooth muscle proliferation, and capillary leak by reducing vascular permeability [79]. NO gives the vessels the ability to self-regulate contraction and relaxation (Fig. 4).
Inhaled NO is very efficient when treating pulmonary PPHT and respiratory failure in infants or newborn suffering from various diseases [10]. But it is not so in the case of children suffering from pulmonary hypertension due to CDH, and the presence and activation of the NOS is still a subject of wide discussion [88, 100]. NO is nevertheless used against pulmonary hypertension in CDH, in combination with mechanical ventilation/HFO, surfactant, and antihypertensive drugs. There has as yet been no randomized trial focused on the role of NO itself to assess its benefits and, worse, one publication reports a poorer outcome in children with CDH treated with NO [29].
Side effects of NO in high concentration are the potentialization of lung injury promoting oxidative stress, the inactivation of the surfactant production, the impairment of ciliary motility, and the increase in tissue inflammation and vascular permeability following plasma extravasation [79]. Inhalation of highly concentrated NO may convert it into a highly toxic peroxynitrite which may activate macrophages and impair surfactant production. The lungs of the newborn seem to be protected against birth-related oxidative stress by an increase in antioxidant activity [83]. Oxidative stress is responsible for dysregulation of the vascular tone, platelet aggregation, and increased vascular permeability. It contributes to apoptosis through changes in ionic transport, activation of enzymes and changes in the cystoskeleton [81].
Guanylate cyclase and cGMP-specific phosphodiesterase
Postnatal pulmonary vascular tone is influenced by various vasoconstrictors or vasodilators. Vasoconstrictors such as ET-1 or thromboxane A2 (TXA2) increase the vascular resistance [102], although ET-1 may also play a role in vasodilation in the newborn [75]. TXA2 and prostacyclin (PGI2) are prostaglandins produced by the degradation of arachidonic acid by the cyclooxygenase enzyme (COX) [17]. Among vasodilators, NO [10, 53] activates soluble Guanylate cyclase (GC) found in vascular smooth muscle and PGI2 activates the smooth-muscle-membrane-bound enzyme adenylate cyclase (AC) [17], thereby increasing the level of cyclic 3′–5′-guanylosine monophosphate (cGMP).
The cGMP dependent proteine kinase (PKG) activates calcium-dependent K+ channels (Kca 2+) through phosphorylation. The resulting hyperpolarization of the cell membrane inhibits the ion influx through voltage operated Ca2+ channels and causes vasodilation [82]. But cGMP is in turn rapidly inactivated by phosphodiesterase (PDE V) enzyme and is transformed into inactive 3′–5′-guanylosine monophosphate (iGMP) which limits the vasodilatory response to NO [118] (Fig. 4). New management strategies in order to diminish persistent pulmonary hypertension at birth are based on the role of agents activating the GC, such as YC-1 (a benzyl indazole derivative) or inhibiting the PDE V, such as sildenafil [86].
ECMO
The use of ECMO is also controversial, and the choice of this interventional therapy is based largely on the belief of individual team leaders. This technique has become a standard treatment in specialized centers for infants born with a CDH, even though one large randomized trial of ECMO reported in the literature reached conclusions which are not very precise and was unable to show its benefit over other techniques [107]. As usual, the main problem in comparing results is the difficulty to guarantee the integrity of the groups of children with CDH who receive a particular treatment, as the criteria applied to select these children are widely divergent [24]. Criteria for the use of ECMO vary widely from center to center, and the final decision is often reached only when an infant shows a clinical deterioration, a deterioration of blood gases, a mechanical ventilation with a peak inspiratory pressure higher than 25 mmHg, a compliance measurement less than 0.25 mL/cmH2O/kg and a tidal volume less than 3.5 mL/kg [92]. Investigators have proposed different formulas based on blood gas components to predict the outcome of babies with CDH and to argue about the use of ECMO: the first is the alveolar-arterial oxygen gradient (AadO2) calculated by the formula: AadO2 = [(713 × FiO2) − PaCO2 / 0.8] − PaO2, FiO2 being the inspiratory fraction of O2 and PaO2 the arterial pressure of O2. The second is the ventilatory index (VI) calculated by the formula: VI = (RR × MAP × PaCO2), RR being the respiratory rate, MAP the median arterial pressure with a good prognosis when the index is less than 1000. The third is a modified VI (MVI) calculated by the formula MVI = (RR × PIP × PaCO2), PIP being the peak inspiratory pressure, and a result of less than 40 offers a good prognosis, a result of more than 80 a bad prognosis. Finally, the most commonly used calculation is the oxygenation index (OI) calculated by the formula OI = (MAP × FiO2/PaO2), with initiation of ECMO for an OI of 40 or greater [57, 93]. Both venovenous and venoarterial techniques have been reported with equally effective results [56].
CDH repair
The rule in most centers is to delay surgery until the pulmonary hypertensive crisis in children born with CDH has been controlled. This period of adaptation at birth permits the stabilization of labile hemodynamic and pulmonary physiology as both lungs are affected by this pathology [42]. Nevertheless, studies tend to show that the timing of surgery makes no difference in the outcome of early and late repair groups [71]. The decision as to the optimum timing of surgery after birth must be discussed by a multidisciplinary team and must first and foremost take into account the stability of the child and its capacity to tolerate “gentle” ventilation with low peak pressure, a FiO2 lower than 50%, a minimum of inhaled NO, and good blood gas values [116]. Serial heart ultrasound examinations can help to assess blood flow shunts and pulmonary hypertension in comparison with systemic pressure. Nevertheless, the repair of a diaphragmatic defect will often worsen pulmonary compliance by reducing the elasticity of the chest wall and increasing the intraabdominal pressure.
Surgery usually begins with a subcostal incision giving access to the entire diaphragm. The spleen, the small intestine and the large intestine are generally herniated through the defect. When the herniated viscera have been reduced, the edges of the diaphragm should be recognized. This obliges the surgeon to dissect the posterior part of the diaphragm, which is often quite thin. Ideally, the diaphragm is closed after the reduction of the viscera with non absorbable interrupted sutures. Mattress sutures or pledgetted sutures can also be used. A laparoscopic approach in the skilled hands of a surgeon who is used to this particular surgical method is also possible and depends largely on the hemodynamic and the pulmonary stability of the child. A transthoracic approach to repair the defect is also described, especially for a CDH on the right side, and affords a nice view for a liver reduction [42].
Primary repair is not always possible. In the presence of a tension too excessive to permit primary repair, of a very large defect in a thin diaphragm or even an absent diaphragm, or of agenesis of the diaphragm, a prosthetic implant may be needed to close the defect. Technically, this implant must be attached all around in order to decrease the risk of recurrence of the hernia, and its attachment to the lateral part to the ribs and to the medial part of the thoracic cavity while safeguarding the passage of the esophagus and the aorta is challenging [69, 93]. There is as yet no optimal patch material. The current materials are too rigid. This rigidity creates problems when the patient grows as the prosthetic implant does not adapt to the growth of the thoracic cavity, leading to thoracic deformation and scoliosis [69]. The development of bioengineered materials, also for other indications than CDH, would be of great interest. Other technical solutions, such as a reversed latissimus dorsi muscle flap for the repair of recurrent CDH, have also been described [98].
Long-term follow-up
Specialized multidisciplinary clinics are emerging in many centers to provide long-term follow-up for children born with CDH. These children require the services of expert pediatricians who are trained in specific areas such as pulmonary, digestive, or musculoskeletal pathologies.
As children with a large defect and those with PPHT will often have multiple problems, a long follow-up is mandatory. The follow-up data for all children born with CDH shows that even those for whom recovery during the neonatal period is relatively easy may still have long-term problems. These problems can be recurrent herniation, delayed growth, chronic lung disease, feeding complications, gastroesophageal reflux, neurological impairment, deafness, and musculoskeletal deformations [49, 52, 105, 106, 108]. Factors such as parental socioeconomic status and education may contribute to making a long-term follow-up more difficult [2, 15].
Pulmonary problems concern obstructive or restrictive pulmonary function anomalies, or a combination of both. Persistent pulmonary hypoplasia produces ventilation perfusion mismatch and chronic lung disease with obstructive airway disease [72, 73]. Children who suffer from these problems may need oxygen support for a long time and are discharged and sent home with the means to pursue this therapy. Chronic lung disease is defined as the need for ventilatory support, chronic bronchodilators, diuretics, or oxygen supplementation [16]. Bronchospasm, asthma, and wheezing are frequently reported in the literature [105]. Bronchial hyperreactivity to pharmacological products has also been reported [106]. A long-term study by Vanamo et al. [106] of young adults born with CDH or with a diaphragmatic eventration and treated between 1948 and 1980 showed that 83% of these patients considered themselves normal, that 12% had asthma and that 4% had recurrent respiratory tract infections. More recently, based on 100 consecutive CDH survivors, Muratore [73] showed that 16% of the patients remained oxygen-dependent for several months after their discharge and 43% diuretic-dependent for a maximum of 30 months after their discharge, and that viral bronchiolitis was strongly prevalent in children under 3 years of age. Kamata et al. [49] showed that morbidity due to recurrent pneumonia was the most prevalent (39%) among 33 CDH survivors who were followed for many years. Keller [52] reported in three patients born with CDH a persistent high pulmonary arterial pressure and a high PVR, measured by cardiac catheterization between the ages of three months and 12 years. Recently, Jaillard et al. [45] found after a 2-year follow-up that chronic lung disease was prevalent in CDH survivors, with a higher prevalence in children treated with ECMO or whose hernia had been repaired with a patch. Finally chest radiography may evidence hyperlucency, hyperinflation, persistent lung hypoplasia, decreased pulmonary vascularity, persistent lung opacities, mediastinal shift, or abnormal diaphragmatic profile [2].
Esophagogastric problems may present as esophageal dysmotility and gastroesophageal reflux (GER) and can occur in more than 50% of CDH children [26, 91]. Failure to thrive due to these feeding-related problems is frequent in this population [73]. The variability in the data reported in various studies concerning the incidence of GER may depend on the method of diagnosis, for instance good clinical investigation, pH monitoring, milk-scan study and upper gastrointestinal contrast. Despite long discussions about the etiology of GER in CDH patients, its pathophysiology has not yet been elucidated and several anatomical hypotheses are proposed, such as kinking of the esophagus at the gastroesophageal junction, shortening of the abdominal esophagus portion, modification of the His angle or absence of the perihiatal diaphragm [2]. The presence of GER mandates a close follow-up of these patients, with appropriate medical treatment and even surgical treatment if necessary, in order to avoid sudden death, chronic pulmonary disease due to bronchoaspiration and failure to thrive [15, 104]. Many other factors, such as chronic lung disease, the use of long-term oxygen, a long period of endotracheal intubation causing delayed swallowing, or the presence of a gastrostomy, contribute to eating difficulties and growth failure. Malrotation is associated with CDH and bowel obstruction is a well-known complication [64].
Deformities of the chest wall such as pectus excavatum and deformities of the spine, including scoliosis, are typical long-term problems which require a long-term follow-up. More than 40% of CDH survivors will suffer from these abnormalities [2]. These malformations are due mainly to the surgical repair with a patch in the case of a large diaphragmatic defect or with stitches fixed to the ribs when closure can be achieved without a patch. Whereas pectus excavatum and vertebral deformities are associated with large diaphragmatic defects, obstructive and/or restrictive pulmonary function anomalies are more often associated with scoliosis [69, 108].
Some studies show that children with CDH treated with ECMO may suffer from delayed neurological development and risk deafness [78]. These effects may be higher in children born with CDH and treated with ECMO than in children born without CDH and treated with ECMO [4, 65]. Other studies find that whether or not ECMO is used makes no difference in the neurological development of children born with CDH [31, 46, 92]. Because ECMO has been associated with neurological complications due to the use of anticoagulant treatment, it is usually reserved for very sick babies with high pulmonary hypertension and a high risk of hypoxic and ischemic brain injuries, characteristics which in themselves entail a prognosis of long-term morbidity. As for sensorineuronal hearing loss, it is a risk for babies born with CDH because of the use of ototoxic medications such as diuretics, muscle relaxants, and antibiotics [31]. Prolonged ventilation is also a factor of risk [112].
Abbreviations
- CDH:
-
congenital diaphragmatic hernia
- PPHT:
-
persistent pulmonary hypertension
- TO:
-
tracheal obstruction
- ECMO:
-
extracorporeal membrane oxygenation
- NO:
-
nitric oxide
- HFO:
-
high-frequency oscillation
- PVR:
-
pulmonary vascular resistance
- US:
-
ultrasound
- LHR:
-
lung–heart-ratio
- MRI:
-
magnetic resonance imaging
- FETO:
-
fetal tracheal occlusion
- VEGF-A:
-
vascular endothelial growth factor-A
- PDGF-B:
-
platelet-derived growth factor-B
- IGF-II:
-
insulin-like growth factor-II
- MAPK:
-
mitogen-activated protein kinase
- ET-1:
-
endothelin-1
- FETENDO:
-
fetal endoscopic surgery
- EXIT:
-
ex utero intrapartum treatment
- iPPROM:
-
iatrogenic preterm rupture of the fetal membrane
- PaCO2 :
-
arterial pressure of CO2
- GC:
-
guanylate cyclase
- PDE V:
-
cGMP-specific phosphodiesterase
- TXA2 :
-
thromboxane A2
- PGI2 :
-
prostacyclin
- COX:
-
cyclooxygenase enzyme
- AC:
-
adenylate cyclase
- cGMP:
-
cyclic 3′–5′-guanylosine monophosphate
- PKG:
-
cGMP dependent proteine kinase
- Kca 2+ :
-
K+ channels calcium dependant
- iGMP:
-
inactive 3′–5′-guanylosine monophosphate
- YC-1:
-
A benzyl indazole derivative
- AadO2 :
-
alveolar-arterial oxygen gradient
- VI:
-
ventilatory index
- RR:
-
respiratory rate
- MAP:
-
median arterial pressure
- MVI:
-
modified ventilatory index
- PIP:
-
peak inspiratory pressure
- OI:
-
oxygenation index
- FiO2 :
-
inspiratory fraction of oxygen
- PaO2 :
-
arterial pressure of O2
- GER:
-
gastroesophageal reflux
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Acknowledgments
The authors are grateful to Mrs. Anne-Marie Wagnière for reviewing the English manuscript and to Dr Sarah Bouchard, Sainte-Justine Hospital, Montreal, Québec, Canada for her constructive advice.
The authors have no financial relationship with the organization that sponsored the research.
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de Buys Roessingh, A.S., Dinh-Xuan, A.T. Congenital diaphragmatic hernia: current status and review of the literature. Eur J Pediatr 168, 393–406 (2009). https://doi.org/10.1007/s00431-008-0904-x
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DOI: https://doi.org/10.1007/s00431-008-0904-x